A novel ZnS
Scientific Reports volume 13, Article number: 2177 (2023) Cite this article
2048 Accesses
1 Citations
4 Altmetric
Metrics details
In this study, new magnetic nanocomposites with shell core structure with different molar ratios of ZnS-CdS were synthesized and their photocatalytic activity in dye removal from synthetic and real effluents in the presence of mercury high pressure lamp as a visible light source was investigated. Optimal photocatalyst with molar ratio of ZnS-CdS 0.25:0.75 showed the best performance in dye removal. Based on the particle distribution histogram of Fe3O4@BNPs@ZnS-CdS (ZnS/CdS: 0.25:0.75), particles with 60–100 nm have the highest abundance. According to the DRS results, hybridization of zinc sulfide with cadmium sulfide reduced the gap and as a result, light absorption was successfully extended to the visible area. The PL results confirm that the optimal photocatalyst (Fe3O4@BNPs@ZnS-CdS) has the lowest electron–hole recombination compared to Fe3O4@BNPs@ZnS and Fe3O4@BNPs@CdS. It should be noted that according to the DLS results, the charge on the optical photocomposite surface is negative at all acidic, alkaline and neutral pHs. One of the significant advantages in this study is the use of high-pressure mercury lamps as a light source, so that these lamps are very economical in terms of economy and also have a long life and excellent efficiency. The optimal photocatalyst not only showed excellent photocatalytic activity for the removal of methylene blue (96.6%) and methyl orange (70.9%) but also for the dye removal of textile effluents (Benton 98.5% and dark olive 100%). Introduced magnetic heterostructures are suitable options for dye removal from textile and spinning wastewaters.
Today, along with industrialization, population growth and increasing unlimited human activities, water, soil and air pollution has also increased and various pollutants such as (dyes, drugs and pesticides) enter the water, which has a direct impact on Environment, human health, animals, birds, underwater creatures1,2,3,4.
Air pollution leads to asthma and respiratory diseases. Soil pollution affects agriculture and causes stomach diseases5,6. Today, the issue of water pollution is the most serious issue because industries such as textiles, printing, dyeing, spinning, leather, etc. discharge large amounts of wastewater containing dyes and toxic substances into the environment, which affects the quality and health of water7,8,9. Dyes are classified into alkaline, acidic, neutral, azo, and radioactive dyes based on their charge and application.
Dyes are one of the most dangerous organic pollutants in industrial effluents, especially textile effluents, which have high toxicity and indestructible structure that cause cancer and genetic mutations, dermatitis, allergies, skin irritation in humans. Dyes may disrupt the process of photosynthesis in aquatic ecosystems because they prevent light from penetrating into the water10,11. The discharged effluent of the textile industry is about 100 tons of colored effluent per year, which leads to water pollution12,13.
Since a significant percentage (70%) of diseases originate from polluted water14, and also due to population growth and declining groundwater and drought, water treatment is the best solution to solve the crisis of shortage of safe water.
Generally, water treatment methods include three basic categories of chemical, physical and biological methods15.
In recent decades, different techniques have been used for the removal of organic pollutants and water treatment, such as membrane separation, use of various adsorbents, use of semiconductors and photocatalysts, some of which, in addition to being complex, are costly1,2. Among the reported techniques, photocatalytic degradation is one of the best methods for water treatment and removal of organic pollutants in wastewater.
So far, semiconductors such as ZnO, ZnS, CdS, TiO2, NiO, Fe2O3, SnO2, CeO, Ag2O have been used2,16,17,18,19. The main problem of most semiconductors is the large band gap, which leads to inactivity of the semiconductor in the visible area. Metal sulfides can receive directly visible light due to their shorter band gap than metal oxides, and are therefore superior to metal oxides20. Zinc sulfide with a band gap of 3.72–3.77 eV has an absorption edge lower than 340 nm, which is active only in the UV region. To increase the activity of semiconductors, they are doping with different percentages of metal oxides or sulfides, various transition metals such as Ni, Fe, Mn and Co and non-metals like S, N, F and O21,22,23,24. Hybridization reduces band gap and allows the photocatalyst to operate in the visible region.
CdS is another semiconductor that has been widely used in the photocatalytic degradation of organic pollutants and water splitting. CdS is an n-type semiconductor with a band gap of 2.42 eV that is able to absorb good light in the visible light region25,26.
Numerous studies have been reported on the synthesis and application of CdS-ZnS hybrid nanostructures. For example, Reddy et al.27 succeeded in synthesizing CdS-ZnS nanoparticles with a core–shell structure and used it for photocatalytic removal of methyl orange dye. In another study, Amiri's research group used CdS-ZnS nanoparticles to investigate the removal of heavy metals28.
Nanotechnology today makes it possible to design and fabricate recyclable hybrid nanocomposites with the efficiency and selectivity of homogeneous catalysts29.
One of the materials that is widely used in the synthesis of nanocatalysts today is iron oxide nanoparticles, which have been considered due to their high biocompatibility. Fe3O4 has superior magnetic properties, good electronic conductivity and high biocompatibility, has attracted more attention than other iron oxides30. The magnetic properties of Fe3O4 can be related to its crystal structure. Magnetite nanoparticles (Fe3O4) (NPs) have many applications in the fields of materials science, physics and chemistry due to their noteworthy properties like being semi-metallic, ferromagnetic and environmentally friendly31,32,33.
Another inexpensive, stable and recyclable solid nanomaterial whose surface is easily functionalized is boehmite. Boehmite is AlOOH, which is a hydrophilic substrate due to its surface being covered with a large number of hydroxy groups, and its surface is easily functionalized34,35. The hybridization of iron nanoparticles with boehmite nanoparticles, in addition to improving the chemical and mechanical properties of nanoparticles, also increases the hydrophilic property of nanoparticles. As a benefit, the hydrophilicity of the support in photocatalytic processes improves the photocatalytic performance.
In this study, the technique of coupling ZnS with CdS was used to reduce the gap band and reduce electron–hole recombination and increase the ability to absorb visible light. Modified magnetic nanocomposites with different molar ratios of ZnS-CdS were synthesized. The photocatalytic activity of these nanocomposites was compared with Fe3O4@BNPs@ ZnS and Fe3O4@BNPs@ CdS to remove methylene blue and methyl orange dyes from synthetic effluents as well as to dye removal of textile and west carton effluents.
Based on the results, the optimal photocatalyst (Fe3O4@BNPs@ ZnS-CdS) (0.25: 0.75) showed the best performance for dye removal in the presence of high pressure mercury lamp as the visible light source.
Materials used in this study are: hydrated aluminum nitrate (Al(NO3)3.9H2O), iron sulfate (FeSO4), iron chloride (FeCl3), sodium hydroxide (NaOH), sodium sulfide (Na2S), cadmium acetate (Cd (OAc)2, zinc acetate (Zn(OAc)2), benzoquinone, ammonium oxalate, silver nitrate, tert-butanol, methyl orange dye (C14H14N3NaO3S, MW: 327.34 g mol−1), methylene blue dye (C16H18ClN3S, M = 319.85 g mol−1), ethanol, etc., all of which were purchased from Merck. The visible light source used in this study is high pressure mercury lamps. In order to check the light intensity of a mercury lamp, a device called lux meter was used and the fluctuation in light intensity was observed. The lowest intensity for visible light is 95 lumens per minute and the highest intensity is 115 lumens per minute, and the average light intensity of the source is 105 lumens per minute. FT‐IR spectra were recorded on a Shimadzu IR-470 spectrometer. TGA was carried out with a STA504 in the temperature range of 25–800 °C at a heating rate of 10 °C min−1. FESEM and EDX measurements were performed by a TESCAN‐MIRA3. XRD pattern was obtained by using a JEOL-JDX-8030 (30 kV, 20 mA). Zeta potential was recorded on SZ-100z Dynamic Light Scattering & Zeta potential analyze (Horiba Jobin). Magnetic property of the photocatalyst was obtained by VSM + FORC vibrating sample magnetometer. The DRS spectrum of Fe3O4@BNPs@ZnS-CdS was recorded by Avaspec-2048-TEC. Also, photoluminescence spectra were gained by Perkin Elmer LS55. Degradation of MB and MO was monitored by UV–visible absorption spectroscopy (UV-1650PC SHIMADZU, Columbia, MD, USA).
First, a mixture of FeCl3 (1.55 g), FeSO4 (1.05 g) and 5% NaOH solution is mixed and placed under N2 gas for 2 h at 90 °C under stirrer condition. After synthesis, the Fe3O4 NPs are separated by an external magnet and washed with water and ethanol. In the next step, a solution of Al(NO3)3 is added to Fe3O4 and then the solution of NaOH is added drop by drop and the mixture is placed in an ultrasonic bath.
Zinc acetate solution was added to Fe3O4@BNPs by sonication and the mixture was refluxed at room temperature for 1 h under intense stirrer. A solution of Na2S was then added and the mixture was refluxed again at 60 °C for 2 h. The prepared Fe3O4@BNPs@ZnS nanoparticles were cooled, separated by an external magnet and dried after rinsing with water at 60 °C.
For the modification of magnetic boehmite with Cd(OAc)2, a solution of cadmium acetate was added to Fe3O4@BNPs under sonication, and the resulting mixture was refluxed at room temperature for 60 min. A solution of sodium sulfide was then added to the mixture and the mixture was refluxed again at 60 °C. Finally, the Fe3O4@BNPs@CdS was washed with water after separation with a strong external magnet and dried overnight at 60 °C.
Separate aqueous solutions of Zn(OAc)2 and Cd(OAc)2 were added to Fe3O4@BNPs (0.5 gr) under sonication, and the mixture was refluxed at rt for 1 h. After that, the mixture was well stirred, a solution of Na2S was added and the mixture was refluxed at 60 °C. The synthesized Fe3O4@BNPs@ ZnS-CdS nanocomposite was separated after cooling, separated by a strong external magnet, washed with water and dried in an oven at 60 °C.
The performance of photocatalysts in dye removal from synthetic effluents of MB and MO at concentrations of 10, 15 and 20 ppm was investigated. Then, important parameters such as the amount of photocatalyst, dye concentration and pH of the environment were surveyed. After the studies, the best photocatalyst (Fe3O4@BNPs@ ZnS-CdS) was chosen.
The photocatalyst’s activity in removing dye from Kashan textile effluent, which includes sausage, benton and dark olive effluents with concentrations of 15–20 ppm, as well as Kermanshah west carton company effluent (dark olive effluent) were examined.
Three photocatalysts were prepared with different molar ratios from ZnS-CdS. The performance of these photocatalysts was evaluated with Fe3O4@BNPs@CdS and Fe3O4@BNPs@ZnS photocatalysts in the visible light region. Based on the results, it was found that the optimal photocatalyst in the visible light region is Fe3O4@BNPs@ZnS-CdS with a molar ratio of ZnS:CdS = 0.25:0.75.
Several techniques like FTIR, XRD, FESEM, EDX, TGA, PL, DRS, BET, VSM, zeta potential were accomplished to corroborate the structure and evaluate the attributes of the best photocatalyst. The schematic steps of the photocatalyst synthesis are illustrated in Fig. 1.
Photocatalyst synthesis steps.
Infrared spectra of MNPs and photocatalyst are shown in Fig. 2. As Fig. 2 shows, the vibrational frequencies appearing in region 480.1 cm−1 are related to the octahedral Fe–O tensile vibration and 621.9 cm−1 are related to the Fe–O tetrahedral tensile vibration. The tensile vibration that appeared in 1133.6 cm−1 belongs to the OH of water molecules. The peak that appeared in 1618.5 cm−1 also belongs to the bending vibration of the hydroxyl group. The vibrations appearing in 3416.1 and 3475.6 cm−1 are related to hydroxy groups on the surface of iron nanoparticles and adsorbed water molecules36.
FT-IR spectra of MNPs and Fe3O4@BNPs@ZnS-CdS.
In the FT-IR spectrum of Fe3O4@BNPs@ ZnS-CdS, the vibrations appearing at 476.9 and 622.9 cm−1 are related to Fe–O and Zn–S, respectively37,38. The peak that appeared in 1619.9 cm−1 is assigned to the bending vibration of the hydroxyl group20. The vibrations appearing in 3415.6 and 3474.8 cm−1 are related to the hydroxy groups on the nanocomposite surface and water molecule. Also, the peaks that appeared in 1135.2 and 1382.4 cm−1 belong to the hydrogen bond between the boehmite plates39.
The XRD spectra of Fe3O4@BNPs and Fe3O4@ BNPs @ ZnS-CdS (0.25: 0.75) are shown in Fig. 3. In the XRD pattern of Fe3O4@MBPs, peaks appeared at 38.30, 35.79, 43.49, 53.92, 57.45 and 63.00 (01-075-0449 JCPDS No.), which have miller coefficients of (440), (511), (422), (400), (311), (220), respectively confirm the cubic structure of Fe3O431. The peaks at 37.51 and 72.72 affirm the presence of BNPs in the structure.
XRD diagrams of Fe3O4@BNPs and Fe3O4@BNPs@ZnS-CdS.
In the XRD pattern of the Fe3O4@BNPs@ZnS-CdS, the peaks at 27.12 (111), (220) 45.62, and 64.01 are related to CdS (JCPDS No. 01-089-0440). The peaks seen at 57.03, 72.02 also show the presence of ZnS in the photocatalyst structure. (JCPDS No. 01-080-0020).
The other peaks which appear at 30.44, 35.72, 45.01.43, 43.38, 63.53 and 74.57, belong to the iron nanoparticles in the photocatalyst structure (JCPDS No. 01-075-0449). The single peak at 72.02 refers to BNPs. Of course, it should be noted that the peaks of boehmite nanoparticles overlap with the peaks of MNPs and CdS. The size of nanoparticles was calculated by well-known Debye Scherrer's formula as follows40:
Here, D is the crystallite size, K is the shape factor, calculated for spherical particles is 0.9, λ = 1.54 Å for Cu and β is full width at half maxima of the highest peak in radian. Based on the equation, the crystalline size for CdS was calculated between 6 and 37.9 nm, and the crystalline size for ZnS was between 26.7 and 29.1 nm.
According to FESEM images, the morphology of magnetic boehmite is spherical and the distribution of particles is uniform (Fig. 4a). As can be seen from Fig. 4b, after rectification with cadmium sulfide- zinc sulfide, in addition to preserving the spherical structure of the nanoparticles, the nanoparticles were also evenly distributed on the surface of the magnetic boehmite.
FESEM images of (a) Fe3O4@BNPs, (b) Fe3O4@BNPs@ZnS-CdS and (c) histogram size distribution of Fe3O4@BNPs@ZnS-CdS, and (d) EDX pattern of Fe3O4@BNPs@ZnS-CdS.
The particle distribution histogram was used to determine the exact particle size and distribution of the particles. According to Fig. 4c, nanoparticles with a size between 60 and 100 nm have the highest frequency in the histogram of Fe3O4@BNPs@ZnS-CdS.
The chemical purity and elemental composition of the prepared Fe3O4@BNPs@ZnS-CdS was investigated by EDX technique. As Fig. 4d shows, all the major elements such as Al, Fe, O, S, Zn, Cd are present in the texture of the photocatalyst.
According to photoluminescence spectroscopy, the shorter the height of the emission spectrum, the lower the electron–hole recombination rate and the synthesized photocatalyst is more active. Figure 5a shows the photoluminescence spectra of the Fe3O4@ BNPs@ ZnS-CdS, Fe3O4@ BNPs @ZnS and Fe3O4@ BNPs-CdS photocatalysts. The emission spectrum of the Fe3O4@BNPs@ ZnS-CdS is the shortest of all, so the electron–hole recombination rate is the lowest for this photocatalyst.
(a) PL spectra of Fe3O4@BNPs@ZnS-CdS, Fe3O4@BNPs@ ZnS and Fe3O4@BNPs@CdS (b) DRS spectrum of nanocomposite and (c) Tauc plots of the Fe3O4@BNPs@ZnS-CdS.
DRS spectrum and band gap of the prepared Fe3O4@BNPs@ ZnS-CdS are shown in Fig. 5b, c, respectively. Band gap was calculated using Tauc plots. The intercept of the tangent to the plot of (αhν)0.5 versus (Eg) expresses the energy of the band gap with a good approximation. It is worth noting that the band gap for synthesized nanocomposites is much shorter (less than 2 eV) compared to the band gap for CdS and ZnS, which are 2.42 eV41 and 3.6 eV42, respectively.
Based on BET test specific surface area (77.66 m2 g−1), particle volume (17.48 cm3 g−1), total pore volume (0.268 cm3 g−1) and mean pore diameter (13.83 nm) for optimal photocatalyst Fe3O4@ BNPs@ZnS-CdS (0.25/0.75) was obtained. Also, based on Langmuir test, particle volume (20.704 cm3 g−1) and specific surface area of 90.114 m2 g−1 were obtained. The nitrogen absorption and desorption diagrams (Fig. 6) confirm that the synthesized photocatalyst has a mesoporous structure and follows the type (IV) isotherm.
N2 absorption and desorption diagrams.
In total, 7.78% of the photocatalyst weight is lost during three failures (Fig. 7a). The first weight loss occurs in the range of 50–100 °C, which is related to adsorbed water and moisture. Subsequent weight loss (3.15%) observed in the range of 100–400 °C can be due to chemical transformations and physical changes such as the change of ZnS structure to wurtzite structure and separation of ZnS and CdS nanoparticles from the photocatalyst surface43,44,45.
(a) TGA diagram for Fe3O4@BNPs@ZnS-CdS and, (b) VSM analysis for Fe3O4@BNPs@ZnS-CdS and Fe3O4@BNPs.
The last loss occurs at 400–800 °C, which is related to the CdS separation and the boehmite crystal phase change46.
Figure 7b shows the magnetic strength of MNPs@BNPs and the final photocatalyst of Fe3O4@ BNPs@ZnS-CdS with a molar ratio of ZnS: CdS = 0.25:0.75. According to VSM analysis, the magnetic strength of MNPs@BNPs is 63.15 emu g−1 and the photocatalyst’s magnetic strength is 42.91 emu g−1. Despite surface modification with ZnS and CdS, the photocatalyst displays remarkable magnetic strength.
The dispersing stability of the photocatalyst nanoparticle is important during the dye removal process. In dye removal process, in order to perform better, the particles of the nanocatalyst surface should be dispersed and not aggregated. The dispersing stability can be predicted by measuring the zeta potential. Zeta potential shows the isoelectric point (the point where the net charge of the photocatalyst surface becomes zero). Of course, in some nanocomposites at all pHs, only the surface charge is negative or positive and the isoelectric point is not observed. At the isoelectric point where the surface charge of the photocatalyst is zero, particles tend to accumulate, which reduces the performance of the photocatalyst47,48. Zeta potential was used to determine the surface charge of the photocatalyst in acidic, neutral and alkaline environments. The zeta potential curves for the photocatalyst at pHs 3, 5 and 8 are shown in Fig. 8, and the values for the zeta potential are shown in Table 1. Also, zeta potential curve against pH for the Fe3O4@BNPs@ZnS-CdS was illustrated in Fig. 8d. For the introduced photocatalyst, the charge on the surface of the photocatalyst is negative at all pHs, and the particles repel each other and do not accumulate.
Gaussian distribution of charge for the Fe3O4@BNPs@ZnS-CdS at different pHs (a) pH = 3, (b) pH = 5, (c) pH = 8 and (d) Zeta potential versus pH curve for Fe3O4@BNPs@ZnS-CdS.
In this study, in addition to Fe3O4@BNPs @CdS and Fe3O4@BNPs@ZnS, three photocatalysts with different molar ratios of zinc sulfide-cadmium sulfide were synthesized and their photocatalytic performance in visible and ultraviolet light was investigated. After laboratory studies, it was found that the most efficient photocatalyst in the visible light region is Fe3O4@ BNPs@ZnS-CdS with a molar ratio of ZnS:CdS = 0.25:0.75, which has unique photocatalytic activity.
The studies were performed with aqueous solution of MB and MO with a concentration of 10 ppm in the presence of the mentioned photocatalysts (Table 2).
The effects of different dosages of Fe3O4@BNPs-ZnS-CdS for photocatalytic degradation in visible light region were explored (Fig. 9). Based on the results, 0.08 g was selected as the optimal amount of the photocatalyst. The use of higher amounts of photocatalyst had little (1%) effect on dye removal.
Effect of Fe3O4@BNPs-ZnS-CdS value on dye removal.
After selecting the light source and achieving the optimum amount of photocatalyst, dye elimination from synthetic MB and MO effluents was performed in the presence of high pressure mercury lamp as visible light source. First, the dye removal reactions for methylene blue and methyl orange were investigated in dark (in the absence of a high-pressure mercury lamp) in the presence of Fe3O4@BNPs-ZnS-CdS. After 1 h, about 5% and 1% of MB and MO dyes were removed, respectively. Also, the effect of photolysis was studied so that the dye removal reactions of MB and MO in the absence of photocatalyst were exposed to high pressure mercury lamp radiation for 1 h. The amount of photolysis was 2% for MO and 3% for MB.
The amount of dye removal in the presence of Fe3O4@BNPs-ZnS-CdS (0.25: 0.75) for 10 ppm MB solution was 96.6% and for 10 ppm MO solution was 70.9% (Fig. 10a, b). In all studies, the amount of photocatalyst is 0.08 gr and the irradiation time is 90 min. In order to achieve the dye removal efficiency, after the appropriate time, the photocatalyst was removed from the environment. Then, degradation of MB and MO were monitored by a UV–Vis spectrophotometer at λ max for each dye. The maximum absorption band is 470 nm for MO and 580 nm for MB.
Photocatalytic removal of (a) MO and (b) MB in the presence of Fe3O4@BNPs-ZnS-CdS and pseudo-first-order kinetic curves for (c) MO and (d) MB.
Dye removal efficiency was calculated using the following equation:
where A0 is the adsorption of dye solution at time = 0 and At is the adsorption of the final sample at time t.
Pseudo-first-order kinetics were obtained for dye elimination after calculations. The rate constant was calculated from the following equation:
In this equation, C0 is the organic dye concentration at t = 0 and CT is the organic dye concentration at time t.
The kinetic graphs and Kap (removal rate constant) for the photocatalytic decolorization of MO and MB are shown in Fig. 10c, d. Based on the calculations, Kap for MO dye (0.0136 min−1) and for MB dye (0.0194 min−1) were obtained and the photocatalytic elimination of MO and MB dyes follows the pseudo-first-order rate constant.
The reproducibility of dye removal reactions for synthetic effluents (MB and MO) was also investigated under optimal conditions up to four times in a row. As expected, dye removal reactions showed excellent reproducibility for both synthetic effluents. Dye removal efficiencies for methyl orange and methylene blue were 96.6% and 70.9% in all four times, respectively.
Based on the results of the zeta potential test, the surface of the photocatalyst has a negative charge, so cationic dyes such as methylene blue are more easily attracted to the surface of the photocatalyst based on electrostatic attraction and are destroyed more efficiently. Anionic dyes such as methyl orange are less absorbed on the surface due to electrostatic repulsion and the amount of dye degradation on the photocatalyst surface is lower.
The effect of increasing dye concentration on dye removal rate for MO and MB dyes in the presence of Fe3O4@BNPs-ZnS-CdS photocatalyst under visible light was checked. For this purpose, concentrations (10, 15 and 20 ppm) of the mentioned dyes were studied and the results are summarized in Table 3. As the table demonstrates, increasing the concentration of the dye solution does not have a significant effect on the percentage of dye elimination.
Photocatalytic dye elimination of MO and MB dyes was surveyed with optimized Fe3O4 @ BNPs-ZnS-CdS photocatalyst under visible light at various pHs (3, 5 and 8). According to Fig. 11, the MO dye removal percent is lower than the neutral medium (70.9%) at all pHs except pH 3. As the diagram illustrates, in the case of MB, the dye elimination in neutral medium (96.6%) is higher than in acidic and alkaline media. The obtained results can be interpreted by the surface charge of the photocatalyst and the nature of the dye. Usually, in photocatalytic processes, dyes are first absorbed on the surface, and then dye degradation occurs on the photocatalyst surface49.
pH effect on the photocatalytic dye removal of MO and MB dyes.
Figure 11 shows that methyl orange, which is an anionic dye, has a higher degradation rate at pH 3, where the surface charge of the photocatalyst is the smallest compared to pH 5 and 8. At pH 3, because the amount of negative charge on the photocatalyst surface is less, the amount of electrostatic repulsion of the photocatalyst surface with the dye molecule (MO) is the lowest, so the dye degradation rate is higher. These results are completely consistent with the results obtained from zeta potential. As for methylene blue, since it is a cationic dye with a negative charge on the surface of the photocatalyst, it has electrostatic attraction. The higher the negative charge, the higher the dye absorption and dye degradation on the photocatalyst surface. As can be seen from Fig. 10, the performance of the photocatalyst at pH 8, which has the highest amount of negative charge, is higher at pH 3 and 5.
It is noteworthy that the retrievability of photocatalyst Fe3O4@BNPs@ZnS-CdS (0.25: 0.75) for MO and MB (10 ppm) dyes under visible light up to five times was investigated. About 5% decrease in photocatalytic activity was observed after five sequential uses (Fig. 12).
The renewability of Fe3O4@BNPs@ZnS-CdS for elimination of MB and MO.
Table 4 compares the photocatalytic performance of synthesized magnetic nanocomposites with some other photocatalytic systems. As can be deduced from the table, the hybrid photocatalyst (Fe3O4@BNPs@ZnS-CdS) is superior to most reported photocatalysts in terms such as dye degradation time and dye removal rate. Also in this study, high pressure mercury lamps were used as a cheap, durable and efficient light source.
Photocatalytic degradation processes for MO and MB are illustrated Eqs. (4–8) and Fig. 13.
Schematic illustration of dye degradation over Fe3O4@BNPs@ZnS-CdS.
The oxidative and reductive reactions are expressed as:
Hydroxyl radicals (·OH) are obtained from the oxidation of absorbed water or absorbed hydroxyl anion (OH-). Also, the presence of oxygen prevents electron–hole recombination. Under the photocatalytic process, the dyes are converted into decomposition products in the presence of hydroxyl radicals and eventually turn into water and carbon dioxide62,63,64.
In order to show active radical species in the photocatalytic process of MB removal, several radical scavengers such as benzoquinone, ammonium oxalate, silver nitrate and tert-butanol were used (Fig. 14). Active species responsible for dye degradation in the presence of photocatalyst are (·OH), superoxide anion radical (O2·−), e− and h+65,66. About 96.6% of methylene blue was removed in the absence of quencher under optimal conditions within 90 min. In this study, benzoquinone, ammonium oxalate, Ag(NO3) and tert-butanol were used as scavengers of O2·−, h+, e− and ·OH, respectively. Dye degradation was decreased about 20% when benzoquinone was added as O2·− quencher. After using ammonium oxalate, which acts as h+ scavenger, the removal of methylene blue decreased by 16%. About 6% reduction in the degradation of MB was observed when using silver nitrate, which indicates that electrons do not play a key role in the photocatalytic degradation of methylene blue.
Effect of various scavengers on the photocatalytic degradation of MB in the presence of high-pressure mercury lamp.
In the presence of tert- butanol (used as a scavenger to quench OH), the degradation rate of MB declined by 15%49. Based on the results of O2·−, h+, and ·OH species are the main species responsible for the photocatalytic degradation of dyes. Based on the results, each scavenger had a different effect on the photocatalytic MB degradation. Also, based on Eqs. (6) and (7), apart from O2−, h+, and OH· mentioned above, other active species such as H+, HO2·, … are created on the surface of the photocatalyst, which can be effective in dye degradation.
Considering that cadmium sulfide is toxic and its release into water and environment is dangerous for the health of living organisms and humans, the issue of Cd+2 leaching from the photocatalyst surface into the solution was investigated. For this purpose, at the end of the photocatalytic dye removal process, about 1 mL of final solution was reacted with sodium sulfide under stirrer. Since cadmium sulfide is insoluble in water, adding sodium sulfide to any solution containing a small amount of cadmium should produce a yellow precipitate of cadmium sulfide. From the point of view of chemistry, the formation of cadmium sulfide precipitate is fast67,68.
In order to evaluate the efficiency of the photocatalyst, dye removal from textile, west carton wastewaters in the presence of visible light and in the absence of catalyst for 30–90 min were investigated. After the desired time, the amount of photolysis was 3% and 2%, respectively. Also, in order to determine the amount of dye absorption by the photocatalyst surface, dye removal of textile and carton effluents were evaluated in the presence of photocatalyst (0.08 gr) and in the absence of visible light at rt for 90 min. After that, the wastewater solutions were examined by UV–visible spectrophotometer and the percentage of dye adsorbed on the photocatalyst surface was 2 and 4, respectively.
The dye removal time for the actual effluent varied from 30 to 90 min and the amount of photocatalyst in all experiments was 0.08 g. In all studies, the reactor is placed in a container containing cold water to keep the temperature constant. Concentrations of 100, 50, 25, 10 ppm of carton effluent were examined using Fe3O4@BNPs@ ZnS-CdS at rt in the presence of high-pressure mercury lamps, which showed 89%, 92.5%, 97.1% and 100% dye removal, respectively.
Three textile effluents (pastel pink, benton and dark olive dyes, with concentrations of 10–20 ppm) in the presence of Fe3O4@ BNPs @ZnS-CdS (0.25: 0.75) were evaluated at rt.
Benton and dark olive effluents were completely bleached in 30 min with 100% efficiency. But pastel pink effluent showed about 68.3% percent of dye removal in 90 min. Kermanshah carton effluent with a concentration of 20 ppm also showed complete color removal in the presence of Fe3O4@ BNPs@ ZnS-CdS (0.25: 0.75) (Fig. 15a–d).
UV–visible spectra for (a) pastel pink (15 ppm), (b) benton (15 ppm), (c) carton wastewater (50 ppm), (d) dark olive (20 ppm).
Photocatalysts are favorable options for removing organic pollutants, especially dyes from water and wastewater. In this study, some magnetic composite photocatalysts were synthesized and their photocatalytic performance in dye elimination from synthetic and real effluents was investigated. In this survey, Fe3O4@BNPs@ZnS-CdS (0.25:0.75) is the best photocatalyst, which was identified by techniques such as FTIR, XRD, FESEM, EDX, TGA, DRS, DLS, PL, VSM, BET, and N2-adsorption desorption. The synthesized Fe3O4@BNPs@ZnS-CdS is stable, recyclable and highly efficient for removing dye from synthetic (MB: 96.6%) and real effluents (68- 100%) in the visible area.
Spherical structure and uniform arrangement of Fe3O4@BNPs@ ZnS-CdS nanoparticles were confirmed by FESEM. Stabilization of ZnS-CdS on the surface of magnetic nanocomposites was confirmed based on IR and XRD spectra. Using Tauc plot, the gap for the photocatalyst was calculated to be less than 2. Charge on the photocatalyst surface is negative at all pHs and therefore the synthesized photocatalyst is more efficient at removing cationic dyes than anionic dyes. Some advantages of this method include: use of relatively cheap materials, easy synthesis method, photocatalyst thermal stability, recyclability of photocatalyst, reproducibility of dye removal results, easy separation of photocatalyst by external magnet, use of cheap and durable lamps. In this study, high-pressure mercury lamps were used as the visible light source, which are very cheap, durable and efficient compared to other visible light lamps on the market.
The data that support the findings of this study are available from the corresponding author upon reasonable request.
Jadhav, S. A., Khedkar, M. V., Somvanshi, S. B. & Jadhav, K. Magnetically retrievable nanoscale nickel ferrites: An active photocatalyst for toxic dye removal applications. Ceram. Int. 47, 28623–28633 (2021).
Article CAS Google Scholar
Nemiwal, M., Zhang, T. C. & Kumar, D. Recent progress in g-C3N4, TiO2 and ZnO based photocatalysts for dye degradation: Strategies to improve photocatalytic activity. Sci. Total Environ. 767, 144896 (2021).
Article ADS CAS Google Scholar
Jamieson, A. J., Malkocs, T., Piertney, S. B., Fujii, T. & Zhang, Z. Bioaccumulation of persistent organic pollutants in the deepest ocean fauna. Nature Ecol. Evol. 1, 1–4 (2017).
Google Scholar
Nidheesh, P., Zhou, M. & Oturan, M. A. An overview on the removal of synthetic dyes from water by electrochemical advanced oxidation processes. Chemosphere 197, 210–227 (2018).
Article ADS CAS Google Scholar
Yu, M.-H. & Tsunoda, H. Environmental Toxicology: Biological and Health Effects of Pollutants (CRC Press, 2004).
Book Google Scholar
Rehman, K., Fatima, F., Waheed, I. & Akash, M. S. H. Prevalence of exposure of heavy metals and their impact on health consequences. J. Cell. Biochem. 119, 157–184 (2018).
Article CAS Google Scholar
Eljamal, R., Eljamal, O., Maamoun, I., Yilmaz, G. & Sugihara, Y. Enhancing the characteristics and reactivity of nZVI: Polymers effect and mechanisms. J. Mol. Liq. 315, 113714 (2020).
Article CAS Google Scholar
Takami, S., Eljamal, O., Khalil, A. M., Eljamal, R. & Matsunaga, N. Development of continuous system based on nanoscale zero valent iron particles for phosphorus removal. J. JSCE 7, 30–42 (2019).
Article Google Scholar
Khan, S. & Malik, A. Environmental Deterioration and Human Health 55–71 (Springer, 2014).
Book Google Scholar
Abukhadra, M. R., Adlii, A. & Bakry, B. M. Green fabrication of bentonite/chitosan@ cobalt oxide composite (BE/CH@ Co) of enhanced adsorption and advanced oxidation removal of Congo red dye and Cr (VI) from water. Int. J. Biol. Macromol. 126, 402–413 (2019).
Article CAS Google Scholar
Chaturvedi, M. et al. Emerging Treatment Technologies for Waste Management 103–132 (Springer, 2021).
Book Google Scholar
Zafar, Z., Fatima, R. & Kim, J.-O. Experimental studies on water matrix and influence of textile effluents on photocatalytic degradation of organic wastewater using Fe–TiO2 nanotubes: Towards commercial application. Environ. Res. 197, 111120 (2021).
Article CAS Google Scholar
Solís, M., Solís, A., Pérez, H. I., Manjarrez, N. & Flores, M. Microbial decolouration of azo dyes: A review. Process Biochem. 47, 1723–1748 (2012).
Article Google Scholar
Riaz, S. & Park, S.-J. An overview of TiO2-based photocatalytic membrane reactors for water and wastewater treatments. J. Ind. Eng. Chem. 84, 23–41 (2020).
Article CAS Google Scholar
Katheresan, V., Kansedo, J. & Lau, S. Y. Efficiency of various recent wastewater dye removal methods: A review. J. Environ. Chem. Eng. 6, 4676–4697 (2018).
Article CAS Google Scholar
Sophia, P. J. et al. Solar induced photocatalytic degradation of methylene blue by CdS/Ag2O nanocomposites. ChemistrySelect 5, 4125–4135 (2020).
Article CAS Google Scholar
Ismail, M. et al. Pollution, toxicity and carcinogenicity of organic dyes and their catalytic bio-remediation. Curr. Pharm. Des. 25, 3645–3663 (2019).
Article CAS Google Scholar
Maamoun, I., Eljamal, O., Eljamal, R., Falyouna, O. & Sugihara, Y. Promoting aqueous and transport characteristics of highly reactive nanoscale zero valent iron via different layered hydroxide coatings. Appl. Surf. Sci. 506, 145018 (2020).
Article CAS Google Scholar
Lamba, R., Umar, A., Mehta, S. & Kansal, S. K. Enhanced visible light driven photocatalytic application of Ag2O decorated ZnO nanorods heterostructures. Sep. Purif. Technol. 183, 341–349 (2017).
Article CAS Google Scholar
Tahir, M. B., Rafique, M., Rafique, M. S., Fatima, N. & Israr, Z. Nanotechnology and Photocatalysis for Environmental Applications 77–96 (Elsevier, 2020).
Book Google Scholar
Patil, S. B. et al. Recent advances in non-metals-doped TiO2 nanostructured photocatalysts for visible-light driven hydrogen production, CO2 reduction and air purification. Int. J. Hydrog. Energy 44, 13022–13039 (2019).
Article CAS Google Scholar
Heiba, Z. K., Mohamed, M. B., El-naggar, A. & Albassam, A. Effect of Mg and Cu doping on structural, optical, electronic, and thermal properties of ZnS quantum dots. J. Mater. Sci. Mater. Electron. 31, 21342–21354 (2020).
Article CAS Google Scholar
Ghorai, S. et al. Insights into local atomic structure of Fe alloyed ZnS nano crystals: Correlation with structural, optical, magnetic and photocatalyst properties. J. Alloys Compd. 805, 363–378 (2019).
Article CAS Google Scholar
Heiba, Z. K., Mohamed, M. B., Plaisier, J. R., El-Naggar, A. & Albassam, A. Influence of (Mn or Co)-doping on structural, magnetic and electronic properties of nano Zn0.75Cd0.25S. Chin. J. Phys. 67, 414–427 (2020).
Article CAS Google Scholar
Karimzadeh, S. & Bahrami, K. Role of L-cysteine and CdS as promoted agents in photocatalytic activity of TiO2 nanoparticles. J. Environ. Chem. Eng. 7, 103454 (2019).
Article Google Scholar
Bao, N., Shen, L., Takata, T. & Domen, K. Self-templated synthesis of nanoporous CdS nanostructures for highly efficient photocatalytic hydrogen production under visible light. Chem. Mater. 20, 110–117 (2008).
Article CAS Google Scholar
Reddy, C. V., Shim, J. & Cho, M. Synthesis, structural, optical and photocatalytic properties of CdS/ZnS core/shell nanoparticles. J. Phys. Chem. Solids 103, 209–217 (2017).
Article ADS CAS Google Scholar
Amiri, O., Hosseinpour-Mashkani, S., Rad, M. M. & Abdvali, F. Sonochemical synthesis and characterization of CdS/ZnS core–shell nanoparticles and application in removal of heavy metals from aqueous solution. Superlattices Microstruct. 66, 67–75 (2014).
Article ADS CAS Google Scholar
Khodamorady, M., Ghobadi, N. & Bahrami, K. Homoselective synthesis of 5-substituted 1H-tetrazoles and one-pot synthesis of 2, 4, 5-trisubstuted imidazole compounds using BNPs@SiO2-TPPTSA as a stable and new reusable nanocatalyst. Appl. Organomet. Chem. 35, e6144 (2021).
Article CAS Google Scholar
Nguyen, M. D., Tran, H.-V., Xu, S. & Lee, T. R. Fe3O4 Nanoparticles: Structures, synthesis, magnetic properties, surface functionalization, and emerging applications. Appl. Sci. 11, 11301 (2021).
Article CAS Google Scholar
Khodamorady, M. & Bahrami, K. Fe3O4@BNPs-CPTMS-Chitosan-Pd (0) as an efficient and stable heterogeneous magnetic nanocatalyst for the chemoselective oxidation of alcohols and homoselective synthesis of 5-subestituted 1H-tetrazoles. ChemistrySelect 4, 8183–8194 (2019).
Article CAS Google Scholar
Ling, D. & Hyeon, T. Chemical design of biocompatible iron oxide nanoparticles for medical applications. Small 9, 1450–1466 (2013).
Article CAS Google Scholar
Laurent, S. et al. Magnetic iron oxide nanoparticles: Synthesis, stabilization, vectorization, physicochemical characterizations, and biological applications. Chem. Rev. 108, 2064–2110 (2008).
Article CAS Google Scholar
Bahrami, K. & Khodamorady, M. Reusable BNPs-SiO2@(CH2)3NHSO3H-catalysed selective oxidation of sulfides to sulfones. Appl. Organomet. Chem. 32, e4553 (2018).
Article Google Scholar
Mohammadi, M., Khodamorady, M., Tahmasbi, B., Bahrami, K. & Ghorbani-Choghamarani, A. Boehmite nanoparticles as versatile support for organic–inorganic hybrid materials: Synthesis, functionalization, and applications in eco-friendly catalysis. J. Ind. Eng. Chem. 97, 1–78 (2021).
Article CAS Google Scholar
Zhu, H. et al. Effective photocatalytic decolorization of methyl orange utilizing TiO2/ZnO/chitosan nanocomposite films under simulated solar irradiation. Desalination 286, 41–48 (2012).
Article CAS Google Scholar
Pathak, C., Mandal, M. K. & Agarwala, V. Synthesis and characterization of zinc sulphide nanoparticles prepared by mechanochemical route. Superlattices Microstruct. 58, 135–143 (2013).
Article ADS CAS Google Scholar
Pathak, C. & Mandal, M. Yellow light emission from Mn2+ doped ZnS nanoparticles. Optoelectron. Adv. Mater. Rapid Commun. 5, 211–214 (2011).
CAS Google Scholar
Khodamorady, M., Sohrabnezhad, S. & Bahrami, K. Efficient one-pot synthetic methods for the preparation of 3, 4-dihydropyrimidinones and 1, 4-dihydropyridine derivatives using BNPs@ SiO2 (CH2)3NHSO3H as a ligand and metal free acidic heterogeneous nano-catalyst. Polyhedron 178, 114340 (2020).
Article CAS Google Scholar
Abdullah, M. et al. Visible-light-driven ZnO/ZnS/MnO2 ternary nanocomposite catalyst: Synthesis, characterization and photocatalytic degradation of methylene blue. Appl. Nanosci. 11, 2361–2370 (2021).
Article ADS CAS Google Scholar
Devadoss, I., Sakthivel, P. & Krishnamoorthy, A. Band gap tailoring and photoluminescence performance of CdS quantum dots for white LED applications: Influence of Ba2+ and Zn2+ ions. J. Mater. Sci. Mater. Electron. 32, 5729–5737 (2021).
Article CAS Google Scholar
Simandan, I.-D. et al. The effect of the deposition method on the structural and optical properties of ZnS thin films. Coatings 11, 1064 (2021).
Article CAS Google Scholar
Tang, Y. et al. Enhanced photocatalytic degradation of tetracycline antibiotics by reduced graphene oxide–CdS/ZnS heterostructure photocatalysts. New J. Chem. 39, 5150–5160 (2015).
Article CAS Google Scholar
Chen, Y., Ren, X., Zhang, K. & Wang, L. Structure and photoluminescence of ZnS/CdS1-xSex nanocomposite prepared by a two-step process. Mat. Sci. Semic. Proc. 100, 42–47 (2019).
Article CAS Google Scholar
Qutub, N. et al. Synthesis, characterization and visible-light driven photocatalysis by differently structured CdS/ZnS sandwich and core–shell nanocomposites. Phys. E Low Dimens. Syst. Nanostruct. 74, 74–86 (2015).
Article ADS CAS Google Scholar
Bahrami, K. & Khodamorady, M. Design of BNPs-TAPC palladium complex as a reusable heterogeneous nanocatalyst for the O-arylation of phenols and N-arylation of amines. Catal. Lett. 149, 688–698 (2019).
Article CAS Google Scholar
Larsson, M., Hill, A. & Duffy, J. Suspension stability; why particle size, zeta potential and rheology are important. Annu. Trans. Nord. Rheol. Soc. 20, 6 (2012).
Google Scholar
Miyauchi, M., Ikezawa, A., Tobimatsu, H., Irie, H. & Hashimoto, K. Zeta potential and photocatalytic activity of nitrogen doped TiO2 thin films. Phys. Chem. Chem. Phys. 6, 865–870 (2004).
Article CAS Google Scholar
Liu, W. et al. Synergistic adsorption-photocatalytic degradation effect and norfloxacin mechanism of ZnO/ZnS@ BC under UV-light irradiation. Sci. Rep. 10, 1–12 (2020).
ADS Google Scholar
Kalpana, K. & Selvaraj, V. Thiourea assisted hydrothermal synthesis of ZnS/CdS/Ag2S nanocatalysts for photocatalytic degradation of Congo red under direct sunlight illumination. RSC Adv. 6, 4227–4236 (2016).
Article ADS CAS Google Scholar
Ciocarlan, R.-G. et al. Novel magnetic nanocomposites containing quaternary ferrites systems Co0.5Zn0.25M0.25Fe2O4 (M= Ni, Cu, Mn, Mg) and TiO2-anatase phase as photocatalysts for wastewater remediation under solar light irradiation. Mater. Sci. Eng. B 230, 1–7 (2018).
Article CAS Google Scholar
Aziz, A. et al. Chitosan-zinc sulfide nanoparticles, characterization and their photocatalytic degradation efficiency for azo dyes. Int. J. Biol. Macromol. 153, 502–512 (2020).
Article CAS Google Scholar
Elmehasseb, I., Kandil, S. & Elgendy, K. Advanced visible-light applications utilizing modified Zn-doped TiO2 nanoparticles via non-metal in situ dual doping for wastewater detoxification. Optik 213, 164654 (2020).
Article ADS CAS Google Scholar
Xu, T. et al. Ultrasound-assisted synthesis of hyper-dispersed type-II tubular Fe3O4@SiO2@ ZnO/ZnS core/shell heterostructure for improved visible-light photocatalysis. J. Alloys Compd. 838, 155689 (2020).
Article CAS Google Scholar
Soltani, N. et al. Enhancement of visible light photocatalytic activity of ZnS and CdS nanoparticles based on organic and inorganic coating. Appl. Surf. Sci. 290, 440–447 (2014).
Article ADS CAS Google Scholar
Wei, H., Wang, L., Li, Z., Ni, S. & Zhao, Q. Synthesis and photocatalytic activity of one-dimensional CdS@TiO2 core-shell heterostructures. Nanomicro Lett. 3, 6–11 (2011).
CAS Google Scholar
Hamadanian, M., Karimzadeh, S., Jabbari, V. & Villagrán, D. Synthesis of cysteine, cobalt and copper-doped TiO2 nanophotocatalysts with excellent visible-light-induced photocatalytic activity. Mat. Sci. Semic. Proc. 41, 168–176 (2016).
Article CAS Google Scholar
Ali, H. Ternary system from mesoporous CdS–ZnS modified with polyaniline for removal of cationic and anionic dyes. Res. Chem. Intermed. 46, 571–592 (2020).
Article CAS Google Scholar
Yang, L. et al. Synthesis of ZnO/ZnS core/shell microsphere and its photocatalytic activity for methylene blue and eosin dyes degradation. J. Dispers. Sci. Technol. 41, 2152–2158 (2020).
Article CAS Google Scholar
Tamer, T. et al. Formation of zinc oxide nanoparticles using alginate as a template for purification of wastewater. Environ. Nanotechnol. Monit. Manag. 10, 112–121 (2018).
Google Scholar
Wang, H.-J. et al. ZnS-based dual nano-semiconductors (ZnS/PbS, ZnS/CdS or ZnS/Ag2S,): A green synthesis route and photocatalytic comparison for removing organic dyes. J. Environ. Chem. Eng. 6, 6771–6779 (2018).
Article CAS Google Scholar
Soltani, N. et al. Visible light-induced degradation of methylene blue in the presence of photocatalytic ZnS and CdS nanoparticles. Int. J. Mol. Sci. 13, 12242–12258 (2012).
Article CAS Google Scholar
Khan, M. E., Khan, M. M. & Cho, M. H. CdS-graphene nanocomposite for efficient visible-light-driven photocatalytic and photoelectrochemical applications. J. Colloid Interface Sci. 482, 221–232 (2016).
Article ADS CAS Google Scholar
Das, D., Biswal, N., Martha, S. & Parida, K. Solar-light induced photodegradation of organic pollutants over CdS-pillared zirconium–titanium phosphate (ZTP). J. Mol. Catal. A: Chem. 349, 36–41 (2011).
Article CAS Google Scholar
Rajagopalan, V. A new synergetic nanocomposite for dye degradation in dark and light. Sci. Rep. 6, 1–10 (2016).
Google Scholar
Lonkar, S. P., Pillai, V. V. & Alhassan, S. M. Facile and scalable production of heterostructured ZnS-ZnO/Graphene nano-photocatalysts for environmental remediation. Sci. Rep. 8, 1–14 (2018).
Article CAS Google Scholar
Mirsalari, S. A. & Nezamzadeh-Ejhieh, A. CdS–Ag3PO4 nano-catalyst: A brief characterization and kinetic study towards methylene blue photodegradation. Mat. Sci. Semicon. Proc. 122, 105455 (2021).
Article CAS Google Scholar
Pant, B., Park, M., Kim, H.-Y. & Park, S.-J. CdS-TiO2 NPs decorated carbonized eggshell membrane for effective removal of organic pollutants: A novel strategy to use a waste material for environmental remediation. J. Alloys Compd. 699, 73–78 (2017).
Article CAS Google Scholar
Download references
The authors are extremely grateful of the Razi University Research Council for support. Also, this study is a project with the number 99026741 under the financial support of the Iran National Science Foundation: INSF.
Department of Organic Chemistry, Faculty of Chemistry, Razi University, Kermanshah, 67144-14971, Iran
Minoo Khodamorady & Kiumars Bahrami
Nanoscience and Nanotechnology Research Center (NNRC), Razi University, Kermanshah, 67144-14971, Iran
Kiumars Bahrami
You can also search for this author in PubMed Google Scholar
You can also search for this author in PubMed Google Scholar
M.K. and K.B. wrote the main manuscript text.M.K. prepared figures 1–15.
Correspondence to Kiumars Bahrami.
The authors declare no competing interests.
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
Reprints and Permissions
Khodamorady, M., Bahrami, K. A novel ZnS-CdS nanocomposite as a visible active photocatalyst for degradation of synthetic and real wastewaters. Sci Rep 13, 2177 (2023). https://doi.org/10.1038/s41598-023-28725-7
Download citation
Received: 02 October 2022
Accepted: 23 January 2023
Published: 07 February 2023
DOI: https://doi.org/10.1038/s41598-023-28725-7
Anyone you share the following link with will be able to read this content:
Sorry, a shareable link is not currently available for this article.
Provided by the Springer Nature SharedIt content-sharing initiative
Scientific Reports (2023)
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.